Display control device, display control method, and recording medium

ABSTRACT

There is provided a display control device including a display controller configured to place a virtual object within an augmented reality space corresponding to a real space in accordance with a recognition result of a real object shown in an image captured by an imaging part, and an operation acquisition part configured to acquire a user operation. When the user operation is a first operation, the display controller causes the virtual object to move within the augmented reality space.

CROSS REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.15/855,377 (filed on Dec. 27, 2017), which is a continuation of U.S.patent application Ser. No. 15/045,246 (filed on Feb. 16, 2016 andissued as U.S. Pat. No. 9,886,798 on Feb. 6, 2018), which is acontinuation of U.S. patent application Ser. No. 14/169,474 (filed onJan. 31, 2014 and issued as U.S. Pat. No. 9,261,954 on Feb. 16, 2016),which claims priority to Japanese Patent Application No. 2013-068395(filed on Mar. 28, 2013), which are all hereby incorporated by referencein their entirety.

BACKGROUND

The present disclosure relates to a display control device, a displaycontrol method, and a recording medium.

A technology called augmented reality (AR) has recently been drawingattention, which shows a user a real space having additional informationsuperimposed thereover. The information shown to the user in the ARtechnology may be visualized using various forms of virtual objects suchas text, icons, or animation. The placement of annotation over an ARspace is generally executed on the basis of recognition inthree-dimensional structure in the real space shown in an image.

A structure from motion (SfM) technique and a simultaneous localizationand mapping (SLAM) technique are known as techniques for recognizing athree-dimensional structure in the real space. In the SfM technique,multiple images are captured from different viewpoints, and, from thoseimages, a three-dimensional structure in the real space shown in theimages is recognized using parallax. The SLAM technique is described inAndrew J. Davison, “Real-Time Simultaneous Localization and Mapping witha Single Camera”, Proceedings of the 9th IEEE International Conferenceon Computer Vision Volume 2, 2003, pp. 1403-1410. JP2009-237845Adiscloses a technique for recognizing three-dimensional positions offeature points, which are selected for initialization in the SLAMtechnique, by using the SfM technique.

SUMMARY

Once a virtual object is placed in an AR space, the virtual objectgenerally maintains a state that is determined in advance independent ofa user's intention. However, there is a case where the user wants tochange the state of the virtual object after the placement of thevirtual object. For example, there is a case the where the user wants tochange the position of the virtual object in the AR space after theplacement of the virtual object.

In light of the foregoing, it is desirable in the present disclosure toprovide technology capable of changing a position of a virtual objectplaced in an AR space in accordance with a user's intention.

According to an embodiment of the present disclosure, there is provideda display control device which includes a display controller configuredto place a virtual object within an augmented reality spacecorresponding to a real space in accordance with a recognition result ofa real object shown in an image captured by an imaging part, and anoperation acquisition part configured to acquire a user operation. Whenthe user operation is a first operation, the display controller causesthe virtual object to move within the augmented reality space.

According to another embodiment of the present disclosure, there isprovided a display control method which includes placing a virtualobject within an augmented reality space corresponding to a real spacein accordance with a recognition result of a real object shown in animage captured by an imaging part, acquiring a user operation, andcausing the virtual object to move within the augmented reality spacewhen the user operation is a first operation.

According to another embodiment of the present disclosure, there isprovided a non-transitory computer-readable recording medium having aprogram recorded thereon, the program being for causing a computer tofunction as a display control device including a display controllerconfigured to place a virtual object within an augmented reality spacecorresponding to a real space in accordance with a recognition result ofa real object shown in an image captured by an imaging part, and anoperation acquisition part configured to acquire a user operation. Whenthe user operation is a first operation, the display controller causesthe virtual object to move within the augmented reality space.

According to one or more of embodiments of the present disclosure, it ispossible to change a position of a virtual object placed in an AR spacein accordance with a user's intention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating an overview of a display control deviceaccording to an embodiment of the present disclosure;

FIG. 2 is a diagram showing a functional configuration example of adisplay control device according to an embodiment of the presentdisclosure;

FIG. 3 is a diagram showing an initial display example of a virtualobject in a case where a gravity vector is not taken into account;

FIG. 4 is a diagram showing comparison results between a case where agravity vector is not taken into account and a case where a gravityvector is taken into account;

FIG. 5 is a diagram showing an initial display example of a virtualobject in a case where a gravity vector is taken into account;

FIG. 6 is a flowchart showing an operation example of an initial displayof a virtual object;

FIG. 7 is a diagram illustrating a case where a virtual object is fixedwithin an augmented reality space;

FIG. 8 is a diagram showing a display example of a case where a virtualobject is fixed within an augmented reality space;

FIG. 9 is a diagram showing a display example of before movement of avirtual object in a case where the virtual object is to be moved withinan augmented reality space;

FIG. 10 is a diagram illustrating a case where a virtual object is movedwithin an augmented reality space;

FIG. 11 is a diagram illustrating a case where a position of a virtualobject is shifted to a movement-capable region;

FIG. 12 is a diagram showing a display example of after movement of avirtual object in a case where the virtual object is moved within anaugmented reality space;

FIG. 13 is a flowchart showing an operation example of controlling aposition/attitude of a virtual object;

FIG. 14 is a diagram showing a display example of before enlargement ofa virtual object in a case where the virtual object is to be enlargedwithin an augmented reality space;

FIG. 15 is a diagram illustrating a case of enlarging a virtual objectwithin an augmented reality space;

FIG. 16 is a diagram showing a display example of after enlargement of avirtual object in a case where the virtual object is to be enlargedwithin an augmented reality space;

FIG. 17 is a flowchart showing an operation example of controlling asize of a virtual object;

FIG. 18 is a diagram showing a display example of before enlargement ofone virtual object in a case where the one virtual object out ofmultiple virtual objects is to be enlarged within an augmented realityspace;

FIG. 19 is a diagram showing a display example of after enlargement ofone virtual object in a case where the one virtual object out ofmultiple virtual objects is enlarged within an augmented reality space;and

FIG. 20 is a diagram showing a hardware configuration example of adisplay control device according to an embodiment of the presentdisclosure.

DETAILED DESCRIPTION OF THE EMBODIMENT(S)

Hereinafter, preferred embodiments of the present disclosure will bedescribed in detail with reference to the appended drawings. Note that,in this specification and the appended drawings, structural elementsthat have substantially the same function and structure are denoted withthe same reference numerals, and repeated explanation of thesestructural elements is omitted.

Further, in this specification and the appended drawings, there are somecases where multiple structural elements that have substantially thesame function and structure are distinguished from one another by beingdenoted with different alphabets or numbers after the same referencenumeral. Note that, in the case where it is not necessary to distinguishthe multiple structural elements that have substantially the samefunction and structure from one another, the multiple structuralelements are denoted with the same reference numeral only.

Further, the “detailed description of the embodiments” will be describedin the following order.

1. Embodiment

-   -   1-1. Overview of display control device    -   1-2. Functional configuration example of display control device    -   1-3. Initial display of virtual object    -   1-4. Position/attitude control on virtual object    -   1-5. Size control on virtual object    -   1-6. Hardware configuration example

2. Conclusion

1. EMBODIMENT 1-1. Overview of Display Control Device

First, an overview of a display control device 10 according to anembodiment of the present disclosure will be described. FIG. 1 is adiagram illustrating an overview of the display control device 10according to an embodiment of the present disclosure. Referring to FIG.1, there is shown the display control device 10 held by a user Ua. Thedisplay control device 10 includes an imaging part 120, which isdirected towards a real space 1, an operation part 140, and a displaypart 160. The imaging part 120 generates an image by capturing the realspace 1.

In the example shown in FIG. 1, the display part 160 displays an imageIm1 captured by the imaging part 120. The user Ua is capable of graspingthe real space 1 by placing a viewpoint on the image Im1 displayed bythe display part 160. However, the image Im1 may not necessarily bedisplayed on the display part 160. For example, in the case where thedisplay part 160 is a transmissive head mounted display (IIMD), thedisplay part 160 does not display the image Im1, and the user Ua mayplace the viewpoint directly on the real space 1 instead of the imageIm1.

Further, a real object A1 is shown in the image Im1. For example, whenthe real object A1 is recognized from the image Im1, the display controldevice 10 places a virtual object in an AR space corresponding to thereal space 1 on the basis of the recognition result of the real objectA1. In this way, the user Ua can view the virtual object placed in theAR space by the display control device 10 via the display part 160. Thereal object A1 may be recognized by the display control device 10, ormay be recognized by a device (for example, server) that is differentfrom the display control device 10.

Here, after the virtual object is placed in the AR space, the virtualobject generally maintains a state that is determined in advanceindependent of the user's intention. However, there is a case where theuser Ua wants to change the state of the virtual object after theplacement of the virtual object. In light of the foregoing, the presentdisclosure proposes technology capable of changing a state of a virtualobject placed in an AR space in accordance with a user's intention.

Note that, although description below will be made as an example of thecase where the display control device 10 is employed as acamera-equipped smartphone, the display control device 10 may also beemployed as a device other than a smartphone. For example, the displaycontrol device 10 may be employed as a video camera, a digital camera, apersonal digital assistant (PDA), a personal computer (PC), a mobilephone, a mobile music playback device, a mobile video processing device,a mobile game console, a telescope, or a binocular.

Heretofore, an overview of a display control device according to anembodiment of the present disclosure has been described.

1-2. Functional Configuration Example of Display Control Device

Subsequently, a functional configuration example of the display controldevice 10 according to an embodiment of the present disclosure will bedescribed. FIG. 2 is a diagram showing a functional configurationexample of the display control device 10 according to an embodiment ofthe present disclosure. As shown in FIG. 2, the display control device10 includes a controller 110, the imaging part 120, a sensor part 130,the operation part 140, a storage 150, and the display part 160.

The controller 110 corresponds to, for example, a processor such as acentral processing unit (CPU) or a digital signal processor (DSP). Thecontroller 110 exhibits various functions that the controller 110 has byexecuting a program stored in the storage 150 or another storage medium.The controller 110 has functional blocks such as an operationacquisition part 111, a sensor data acquisition part 112, an imagerecognition part 113, an environment recognition part 114, and a displaycontroller 115. The functions of the respective functional blocks willbe described later.

The imaging part 120 is a camera module that captures an image. Theimaging part 120 captures a real space using an image sensor such as acharge coupled device (CCD) or a complementary metal oxide semiconductor(CMOS), and generates an image. The image generated by the imaging part120 is output to the controller 110. Note that, although the imagingpart 120 is provided in an integrated manner with the display controldevice 10 in the example shown in FIG. 2, the imaging part 120 may beprovided separately from the display control device 10. For example, animaging device connected to the display control device 10 via wire orradio may be used as the imaging part 120.

The sensor part 130 acquires sensor data. For example, the sensor part130 includes a 3-axis acceleration sensor. The 3-axis accelerationsensor measures gravitational acceleration applied to the imaging part120, and generates sensor data (acceleration data) that shows the sizeand the direction of the gravitational acceleration in three dimensions.Additionally, the sensor part 130 may include a geomagnetic sensor. Thegeomagnetic sensor generates sensor data (geomagnetic data) showing thedirection of geomagnetism of the imaging part 120 in a coordinatesystem. Further, the sensor part 130 may also include a positioningsensor (for example, global positioning system (GPS) sensor). Thepositioning sensor generates sensor data (positioning data) showing thelatitude and the longitude of the display control device 10 in the realspace. Note that, although the sensor part 130 is provided in anintegrated manner with the display control device 10 in the exampleshown in FIG. 2, the sensor part 130 may be provided separately from thedisplay control device 10.

The operation part 140 detects an operation performed by a user andoutputs the operation to the controller 110. In the presentspecification, since a case is assumed where the operation part 140 isformed of a touch panel, the operation performed by the user correspondsto an operation of tapping the touch panel. However, the operation part140 may also be formed of hardware other than a touch panel (forexample, button). Note that, although the operation part 140 is providedin an integrated manner with the display control device 10 in theexample shown in FIG. 2, the operation part 140 may be providedseparately from the display control device 10.

The storage 150 uses a recording medium such as semiconductor memory ora hard disk to store a program for causing the controller 110 tooperate. Further, for example, the storage 150 can also store varioustypes of data (for example, various types of sensor data and virtualobjects) used by the program. Note that, although the storage 150 isprovided in an integrated manner with the display control device 10 inthe example shown in FIG. 2, the storage 150 may be provided separatelyfrom display control device 10.

The display part 160 displays various types of information in accordancewith the control performed by the display controller 115. For example,the display part 160 displays an image of an AR application generated bythe display control device 10. The display part 160 is formed of, forexample, a liquid crystal display (LCD) or an organicelectroluminescence (EL) display device. Note that, although the displaypart 160 is provided in an integrated manner with the display controldevice 10 in the example shown in FIG. 2, the display part 160 may beprovided separately from the display control device 10. For example, adisplay device connected to the display control device 10 via wire orradio may be used as the display part 160.

Heretofore, a functional configuration example of the display controldevice 10 according to an embodiment of the present disclosure has beendescribed.

From the next section onwards, the description of the functions that thedisplay control device 10 according to an embodiment of the presentdisclosure has will be continued in the following order: “Initialdisplay of virtual object”; “Position/attitude control on virtualobject”; and “Size control on virtual object”. Note that all thefunctions described in the respective sections of “Initial display ofvirtual object”, “Position/attitude control on virtual object”, and“Size control on virtual object” may be used in combination, or onlysome of the functions may be used in combination.

1-3. Initial Display of Virtual Object

First, an initial display of a virtual object will be described.Referring to FIG. 3, in an image Im2 captured by the imaging part 120,there is shown a real object A1. Further, the real object A1 isrecognized by the image recognition part 113, and a virtual object V1associated with the recognition result is placed in an AR spacecorresponding to the real space by the display controller 115.Accordingly, the display part 160 displays the virtual object V1 placedin the AR space.

In more detail, when the image recognition part 113 recognizes theposition and the attitude of the real object A1, the display controller115 identifies the position of the virtual object V1 in accordance withthe position of the real object A1, also identifies the attitude of thevirtual object V1 in accordance with the attitude of the real object A1,and places the virtual object V1 in accordance with the identifiedposition and attitude. The relationship between the position of the realobject A1 and the position of the virtual object V1 may be determined inadvance. Further, the relationship between the attitude of the realobject A1 and the attitude of the virtual object V1 may also bedetermined in advance.

For example, the image recognition part 113 checks a partial imageincluded in the image Im2 against patches of respective feature pointsincluded in feature data, and detects feature points included in theimage Im2. In the case where the feature points belonging to the realobject A1 are detected in high density in a region within the image Im2,the image recognition part 113 may recognize that the real object A1 isshown in the region. The image recognition part 113 may furtherrecognize the position and the attitude of the recognized real object A1on the basis of positional relationship between the detected featurepoints and three-dimensional shape data.

In the example shown in FIG. 3, when the user Ua visits an aquarium,there is the real object A1 at the back wall surface of a water tank.When the user Ua holds the imaging part 120 over the real object A1 andthe image recognition part 113 recognizes the real object A1, a sharkserving as an example of the virtual object V1 associated with therecognition result is placed in the AR space corresponding to the realspace by the display controller 115. However, the virtual object V1 maybe any virtual object other than the shark.

Further, in the example shown in FIG. 3, the display controller 115causes the size of the virtual object V1 in the AR space to be displayedas a size M1. The size of the virtual object V1 in the AR space may bedetermined by a technique to be described later. Further, the displaycontroller 115 causes the ratio of the current size of the virtualobject V1 in the AR space to the real size of the virtual object V1 tobe displayed as a ratio N1. For example, the real size of the virtualobject V1 may also be registered in advance. Note that the real size ofthe virtual object means the size of the real object corresponding tothe virtual object. In the case where a shark is assumed as the virtualobject, the real size of the virtual object means the size of the sharkas the real object.

Here, for example, in the case where the attitude of the real object A1is not normal, it is assumed that the attitude of the virtual object V1placed in the AR space is not normal. For example, let us assume thecase where the relationship between the attitude of the real object A1and the attitude of the virtual object V1 is determined such that theattitude of the virtual object V1 is rendered normal when the realobject A1 is placed on the horizontal plane. In this case, as shown inFIG. 3, it can be expected that the attitude of the virtual object V1becomes not normal in the case where the real object A1 is present onthe wall surface.

Accordingly, this section proposes technology for rendering the initialdisplay of the virtual object V1 normal, independently of whether theattitude of the real object A1 is normal.

As shown in FIG. 4, let us assume that a real object A0 is placed in anormal attitude. In this case, the attitude of a virtual object V0placed in the AR space becomes normal in accordance with the positionand the attitude of the real object A0. On the other hand, let us assumethat a real object A1 is placed in an attitude that is not normal asdescribed above. In this case, the attitude of a virtual object V1placed in the AR space becomes not normal in accordance with theposition and the attitude of the real object A1.

In such a case, for example, the display controller 115 may place avirtual object V2 in a manner that the attitude of the virtual object V2becomes an attitude corresponding to a gravity vector G Regarding thegravity vector G, when the sensor part 130 detects acceleration data,the acceleration data may be acquired as the gravity vector G by thesensor data acquisition part 112. For example, if a relationship that isto be satisfied between the direction indicated by the gravity vector Gand the attitude of the virtual object V1 is determined in advance, thedisplay controller 115 may rotate the virtual object V1 so as to satisfythe relationship.

Referring to FIG. 4, there is shown, as the virtual object V2, theresult obtained by rotating the virtual object V1 such that therelationship that is to be satisfied between the direction indicated bythe gravity vector G and the attitude of the virtual object V1 issatisfied. Further, referring to FIG. 5, an image Im3 is captured, andthere is shown, as the virtual object V2, the result obtained byrotating the virtual object V1 such that the relationship is satisfied.In this way, by changing the attitude of the virtual object V1 with thegravity vector G taken into account, it becomes possible to place thevirtual object V1 in the AR space such that the virtual object V1 has anormal attitude.

In more detail, the display controller 115 may grasp what attitude thereal object A1 is in based on the relationship between the directionindicated by the gravity vector G and the opposite vector of the normalvector of the real object A1, and may determine a degree of rotation ofthe virtual object V1 in accordance with the attitude of the real objectA1.

For example, in the case where the angle between the direction indicatedby the gravity vector G and the opposite vector of the normal vector ofthe real object A1 is more than or equal to 0 degree and less than 45degrees (or less than or equal to 45 degrees), the display controller115 may determine that the real object A1 is placed on a floor surface.In such a case, when the virtual object V1 is placed in the normalvector direction of the real object A1, it is not necessary that thedisplay controller 115 rotate the virtual object V1.

Further, for example, in the case where the angle between the directionindicated by the gravity vector G and the opposite vector of the normalvector of the real object A1 is more than or equal to 45 degrees (ormore than 45 degrees) and less than 135 degrees, the display controller115 may determine that the real object A1 is pasted on a wall surface.In such a case, when the virtual object V1 is placed in the normalvector direction of the real object A1, the display controller 115 mayrotate the virtual object V1 90 degrees in the direction indicated bythe gravity vector G.

Further, for example, in the case where the angle between the directionindicated by the gravity vector G and the opposite vector of the normalvector of the real object A1 is more than or equal to 135 degrees (ormore than 135 degrees) and less than or equal to 180 degrees, thedisplay controller 115 may determine that the real object A1 is pastedon a ceiling. In such a case, when the virtual object V1 is placed inthe normal vector direction of the real object A1, the displaycontroller 115 may rotate the virtual object V1 180 degrees in thedirection indicated by the gravity vector G.

FIG. 6 is a flowchart showing an operation example of an initial displayof the virtual object V2. First, when the imaging part 120 captures animage, the image recognition part 113 recognizes the real object A1 fromthe image captured by the imaging part 120 (S11). The image recognitionpart 113 calculates the position and the attitude of the real object A1(S12). Further, the sensor data acquisition part 112 acquires sensordata detected by the sensor part 130 (S13), and identifies a gravityvector on the basis of the sensor data (S14). For example, in the casewhere acceleration data is acquired as the sensor data, the accelerationdata may be identified as the gravity vector.

The display controller 115 identifies the position of the virtual objectV1 in accordance with the position of the real object A1 (S15).Subsequently, the display controller 115 identifies the attitude of avirtual object in accordance with the gravity vector (S16). The displaycontroller 115 places the virtual object V2 in the AR space on the basisof the identified position and attitude (S17). In the case where therecognition of real object A1 performed by the image recognition part113 is not continued (“No” in S18), the controller 110 may complete theoperation, and in the case where the recognition of the real object A1performed by the image recognition part 113 is being continued (“Yes” inS18), the processing may return to step S11.

Heretofore, “Initial display of virtual object” has been described.

1-4. Position/Attitude Control on Virtual Object

Subsequently, position/attitude control on a virtual object will bedescribed. Referring to FIG. 7, the display controller 115 places thevirtual object V2 in an AR space 2. Here, as shown in FIG. 7, theposition and attitude of the imaging part 120 are represented by P1 andQ1, respectively, and the position and the attitude of the virtualobject V2 are represented by p1 and q1, respectively. Let us assumethat, in this state, the position and the attitude of the imaging part120 are changed to P2 and Q2, respectively. In this case, the virtualobject V2 is generally fixed within the AR space. However, there is acase where the user Ua wants to change the position of the virtualobject V2 in the AR space after the placement of the virtual object V2.

For example, assuming a scene where the user Ua is about to take aphotograph of the virtual object V2, there may be a case where the userUa wants to move the virtual object V2 and decides a background, andthen take a photograph of the virtual object V2. Further, for example,in the case where the user Ua does not want to include the real objectA1 within an imaging range, a case is assumed where the user Ua wants totake a photograph of the virtual object V2 after moving the virtualobject V2 to a position such that the real object A1 is out of theimaging range.

Accordingly, this section proposes technology for making it possible tochange the position of the virtual object V2 placed in the AR space inaccordance with a user's intention.

First, description will be made of the case where the position of thevirtual object V2 placed in the AR space is not changed. For example,the display controller 115 may fix the virtual object V2 within the ARspace while there is no first operation being performed. The firstoperation may be any operation, and may be an operation of specifyingthe virtual object V2. Hereinafter, description will be made as anexample of the case where the operation of specifying the virtual objectV2 is used as the first operation. The operation of specifying thevirtual object V2 may include, for example, an operation of specifyingthe virtual object V2 using one or more operating objects.

The operation of specifying the virtual object V2 may be an operation oftapping the virtual object V2. Further, the operation of specifying thevirtual object V2 may be, in the case where the display part 160 is atransmissive HMD, an operation of holding the virtual object V2 betweentwo operating objects (for example, two fingers). Alternatively, theoperation of specifying the virtual object V2 may be a gesture ofturning a line of sight to the virtual object V2. For example, theoperation of specifying the virtual object V2 may be performed duringthe time period from the start to the release of specifying the virtualobject V2.

As shown in FIG. 7, let us assume that the position and the attitude ofthe imaging part 120 are changed to P2 and Q2, respectively, under thestate where the virtual object V2 is not specified. Under the statewhere the virtual object V2 is not specified, the display controller 115may fix the virtual object V2 within the AR space. For example, underthe state where the virtual object V2 is not specified, the displaycontroller 115 may cause the size of the virtual object V2 in the imageto be changed in accordance with the distance between the imaging part120 and the virtual object V2.

For example, referring to FIG. 8, an image Im4 is captured. As shown inFIG. 8, under the state where the virtual object V2 is not specified,the display controller 115 may make the size of the virtual object V2 inthe image Im4 to decrease, as the user Ua moves away from the virtualobject V2 and the distance between the imaging part 120 and the virtualobject V2 increases.

Further, under the state where the virtual object V2 is not specified,the display controller 115 may cause the attitude of the virtual objectV2 in the image to be changed in accordance with the attitude of thevirtual object V2 based on the imaging part 120. For example, under thestate where the virtual object V2 is not specified, in the case wherethe user Ua changes an imaging direction and the attitude of the virtualobject V2 based on the imaging part 120 has changed, the displaycontroller 115 may cause the attitude of the virtual object V2 in theimage to be changed in accordance with the changed attitude.

On the other hand, in the case where a user operation acquired by theoperation acquisition part 111 is an operation of specifying the virtualobject V2, the display controller 115 may cause the virtual object V2 tomove within the AR space. While the display controller 115 causes thevirtual object V2 to move within the AR space, the display controller115 may control any output. For example, while the display controller115 causes the virtual object V2 to move within the AR space, thedisplay controller 115 may cause the fact that the virtual object V2 isbeing moved to be displayed.

For example, as shown in FIG. 9, the display controller 115 may cause amessage L1 to be displayed, the message L1 showing that the virtualobject V2 is “moving”. However, the fact that the virtual object V2 isbeing moved may be shown without using a message. For example, thedisplay controller 115 may cause the fact that the virtual object V2 isbeing moved to be displayed by allowing the virtual object V2 to have amotion.

In what way to move the virtual object V2 is not limited. As an example,as shown in FIG. 10, under the state where the virtual object V2 isspecified, in the case where the position of the imaging part 120 ischanged from P2 to P3 and the attitude of the imaging part 120 ischanged from Q2 to Q3, the display controller 115 may cause the virtualobject V2 to move within the AR space under the state where the relativeposition relationship between the imaging part 120 and the virtualobject V2 is maintained.

In the case where the virtual object V2 is moved within the AR space inthis way, the virtual object V2 may be fixed in the imaging range.Accordingly, the display controller 115 may cause some kind of virtualobject (for example, a stick that pierces the virtual object V2)indicating that virtual object V2 is fixed to the imaging range to bedisplayed. In the example shown in FIG. 10, the position of the virtualobject V2 is moved from p1 to p2, and the attitude of the virtual objectV2 is changed from q1 to q2.

Further, the display controller 115 may grasp the position and theattitude of the imaging part 120 in any technique. For example, thedisplay controller 115 may grasp the position and the attitude of theimaging part 120 on the basis of a result of environment recognitionperformed by the environment recognition part 114. As the environmentrecognition performed by the environment recognition part 114,calculation based on the SLAM technique can be used. According to thecalculation based on the SLAM technique, a three-dimensional structureof a real space shown in an image captured by the imaging part 120 and aposition and an attitude of the imaging part 120 can be recognizeddynamically.

Note that FIG. 10 shows an example in which the display controller 115causes one virtual object V2 specified by an operation for specifyingthe virtual object V2 to move within the AR space, but the number ofvirtual objects to be moved may not be one. In the case where a useroperation acquired by the operation acquisition part 111 is an operationfor specifying a virtual object, the display controller 115 may causeone or multiple virtual objects specified by the operation forspecifying a virtual object to move within the AR space.

According to such a configuration, the user Ua can cause the virtualobject V2 to move by changing the position and the attitude of theimaging part 120 during the time period from the start to the release ofthe operation of specifying the virtual object V2. Accordingly, a senseas if the virtual object V2 is moved using a drag and drop operation canbe given to the user Ua, and the user Ua can intuitively move thevirtual object V2 within the AR space.

Here, it is expected that an environment of the virtual object V2 at adestination may be any of various environments. Accordingly, the displaycontroller 115 may control the virtual object V2 on the basis of theenvironment of the virtual object V2 at the destination. For example, asshown in FIG. 11, in the case where the environment of the virtualobject V2 at the destination is a movement-incapable region R2, thedisplay controller 115 may cause the position of the virtual object V2to be shifted to a movement-capable region R1. The movement-incapableregion R2 may be a region in which it is not possible for a real objectto enter from outside, such as a pillar and a wall.

Alternatively, the display controller 115 may cause the virtual objectV2 to perform a motion associated with the environment of the virtualobject V2 at the destination. For example, in the case where theenvironment of the virtual object V2 at the destination is the sea, thedisplay controller 115 may express the virtual object V2 in an animationin which the virtual object V2 starts swimming. Further, for example, inthe case where the environment of the virtual object V2 at thedestination is the land, the display controller 115 may express thevirtual object V2 in an animation in which the virtual object V2 stopsswimming.

FIG. 12 is a diagram showing a display example of after movement of thevirtual object V2 in a case where the virtual object V2 is to be movedwithin the AR space. Referring to FIG. 12, an image Im5 is captured, andthe virtual object V2 is being moved. In this way, the position of thevirtual object V2 placed in the AR space can be changed in accordancewith a user's intention. In the example shown in FIG. 12, an aquarium isused as the background, and the family of the user Ua and the virtualobject V2 can be fit into a single imaging range.

FIG. 13 is a flowchart showing an operation example of controlling aposition/attitude of the virtual object V2. First, the environmentrecognition part 114 starts environment recognition (S21), and theoperation acquisition part 111 acquires a user operation. In the casewhere an operation for specifying the virtual object V2 is not performed(“No” in S22), the display controller 115 fixes the virtual object V2 inthe AR space (S23), and the controller 110 proceeds to S27.

On the other hand, in the case where an operation for specifying thevirtual object V2 is performed (“Yes” in S22), the display controller115 causes the virtual object V2 to move in the AR space (S24), andcontrols the virtual object V2 on the basis of an environment at adestination (S25). In addition, the display controller 115 causes thefact that the virtual object V2 is being moved to be displayed (S26),and the controller 110 proceeds to S27. In the case where environmentrecognition performed by the environment recognition part 114 is notcontinued (“No” in S27), the controller 110 may complete the operation,and in the case where the environment recognition performed by theenvironment recognition part 114 is being continued (“Yes” in S27), theprocessing may return to step S22.

Heretofore, “Position/attitude control on virtual object” has beendescribed.

1-5. Size Control on Virtual Object

Subsequently, size control on a virtual object will be described.Referring to FIG. 14, the display controller 115 places the virtualobject V2 in an AR space 2. Here, the size of the virtual object V2 inan image is generally decided in accordance with the size of the realobject A1 in the image. However, there is a case where the user Ua wantsto change the size of the virtual object V2 in the AR space after theplacement of the virtual object V2.

For example, assuming a scene where the user Ua is about to take aphotograph of the virtual object V2, there may be a case where the userUa wants to increase the size of the virtual object V2 in the AR spaceup to the real size, and then take a photograph of the virtual objectV2. Accordingly, this section proposes technology for making it possibleto change the size in the AR space of the virtual object V2 placed inthe AR space in accordance with a user's intention.

Specifically, in the case where a user operation is a second operation,the display controller 115 may change the size of the virtual object V2in the AR space on the basis of the second operation. The secondoperation may be any operation, and may include, as shown in FIG. 14 forexample, an operation of changing a distance between multiple operatingobjects. For example, in the case where the user operation is anoperation of making the distance between multiple operating objectssmaller (for example, pinch-close operation), the size of the virtualobject V2 in the AR space may be reduced.

Further, for example, in the case where the user operation is anoperation of making the distance between multiple operating objectslarger (for example, pinch-open operation), the size of the virtualobject V2 in the AR space may be increased. Referring to FIG. 15, as aresult of increasing the size of the virtual object in the AR space,there is shown a state where the virtual object placed in the AR spaceis changed from the virtual object V2 to a virtual object V3.

FIG. 16 is a diagram showing a display example of after enlargement of avirtual object in a case where the virtual object is to be enlargedwithin an augmented reality space. As shown in FIG. 16, in the casewhere it is possible to enlarge the virtual object V3, a limit onenlargement may be set for the virtual object V3. (Alternatively, in thecase where it is possible to reduce the virtual object V3, a limit onreduction may be set for the virtual object V3.) For example, FIG. 16shows an image Im6, and as shown in FIG. 16, the display controller 115may stop enlarging the virtual object when the size of the virtualobject in the AR space has reached the real size of the virtual object.

Further, in the case where the size of the virtual object in the ARspace has reached the real size of the virtual object, the displaycontroller 115 may cause the fact that the size of the virtual object inthe AR space has reached the real size of the virtual object to bedisplayed. For example, as shown in FIG. 16, the display controller 115may cause a message L2 to be displayed, which shows that the size of thevirtual object in the AR space has reached the real size.

Further, in the example shown in FIG. 16, the display controller 115causes a size M2 to be displayed, the size M2 being the size of thevirtual object V3 displayed in the AR space. Further, the displaycontroller 115 causes a ratio N2 to be displayed, the ratio N2 being theratio of the current size of the virtual object V3 in the AR space tothe real size of the virtual object V3.

Here, a technique of determining whether the size of the virtual objectin the AR space has reached the real size of the virtual object is notparticularly limited. As an example, the display controller 115 maydetermine whether the size of the virtual object in the AR space hasreached the real size of the virtual object on the basis of known datarelated to the real size of the real object A1, the size of the realobject A1 in the image, and known data related to the real size of thevirtual object.

More specifically, in the case where the real size of the real object A1is registered as the known data, the display controller 115 maycalculate the ratio of the real size of the real object A1 to the sizeof the real object A1 in the image. In this way, when the real object A1and the virtual object are placed at the same distance from the imagingpart 120, the display controller 115 can calculate the size of thevirtual object in the AR space by multiplying the size of the virtualobject in the image by the calculated ratio.

Note that, even when the distance between the real object A1 and theimaging part 120 is different from the distance between the virtualobject and the imaging part 120, the size of the virtual object in theAR space can be calculated. For example, with the use of the ratio ofthe real size of the real object A1 to the size of the real object A1 inthe image, the position of the real object A1 in the real space based onthe position of the imaging part 120 can be grasped. Further, even ifthe user Ua moves the imaging part 120 to a position at which thevirtual object is included in the imaging range, the display controller115 can grasp, on the basis of a result of environment recognition, theposition of the real object A1 in the real space and the position of thevirtual object in the AR space based on the position of the imaging part120.

Then, using the position of the virtual object in the AR space based onthe position of the imaging part 120, the display controller 115 cangrasp the size of the virtual object in the AR space from the size ofthe virtual object in the image. In the case where the real size of thevirtual object is registered as the known data, the display controller115 can determine whether the size of the virtual object in the AR spacehas reached the real size of the virtual object by comparing the realsize of the virtual object with the size of the virtual object in the ARspace.

Since a size of a virtual object in an image is generally determined inaccordance with a size of a real object in the image, it was necessary,in order to place the virtual object having a desired size in the ARspace, to adjust the size of the real object in the real space or toadjust the size of the real object shown in the image. With the sizecontrol on the virtual object according to the present embodiment, itbecomes possible to place the virtual object having a desired size inthe AR space in accordance with the user operation.

FIG. 17 is a flowchart showing an operation example of controlling asize of a virtual object. First, the environment recognition part 114starts environment recognition (S31), and the operation acquisition part111 acquires a user operation. In the case where there is no sizechanging operation (“No” in S32), the controller 110 proceeds to S37.

On the other hand, in the case where there is a size changing operation(“Yes” in S32), the display controller adjusts the size of the virtualobject in the AR space (S33), and in the case where the size of thevirtual object in the AR space has not reached the real size (“No” inS34), the controller 110 proceeds to S37. On the other hand, in the casewhere the size of the virtual object in the AR space has reached thereal size (“Yes” in S34), the display controller 115 stops enlarging thevirtual object (S35), causes the fact that the size of the virtualobject in the AR space has reached the real size to be displayed (S36),and the controller 110 proceeds to S37.

In the case where the environment recognition performed by theenvironment recognition part 114 is not continued (“No” in S37), thecontroller 110 may complete the operation, and in the case where theenvironment recognition performed by the environment recognition part114 is being continued (“Yes” in S37), the processing may return to stepS31.

Heretofore, the case where the number of virtual objects is one has beendescribed, but there may be a case where the number of virtual objectsmay be two or more. In such a case, the sizes of some of the multiplevirtual objects may be adjusted, or the sizes of all the multiplevirtual objects may be adjusted. For example, the display controller 115may select a virtual object the size of which is to be changed inaccordance with the distances from the imaging part 120 to therespective virtual objects.

FIG. 18 is a diagram showing a display example of before enlargement ofthe virtual object V2 in the case where the virtual object V2 out ofvirtual objects V11 and V2 is to be enlarged within the AR space.Referring to FIG. 18, an image Im7 is captured. FIG. 19 is a diagramshowing a display example of after enlargement of the virtual object V2.Referring to FIG. 18, an image Im8 is captured. In the examples shown inthose figures, the display controller 115 selects the virtual objectthat is the nearest from the imaging part 120 (virtual object placed atthe nearest side when seen from the imaging part 120) as the target thesize of which is to be changed.

In this case, for example, the virtual object that is the nearest fromthe imaging part 120 may be displayed in a mode which can bedistinguished from the other virtual objects. For example, the virtualobject that is the nearest from the imaging part 120 may be displayed ina manner that the virtual object has a motion and the other virtualobjects may be displayed in a manner that they stand still. However, thetechnique for adjusting sizes of some of the multiple virtual objects isnot limited thereto.

For example, in the case where the user Ua conducts a selectionoperation, the display controller 115 may select a virtual object thesize of which is to be changed on the basis of the selection operation.The selection operation is not limited, and may be a tap operation, forexample. Alternatively, in the case where the size changing operation isa pinch-open operation or a pinch-close operation, the displaycontroller 115 may select the virtual object that is directly specifiedby the operating object in the course of the pinch-open operation or thepinch-close operation.

Heretofore, “Size control on virtual object” has been described.

1-6. Hardware Configuration Example

Next, a hardware configuration example of the display control device 10according to an embodiment of the present disclosure will be described.FIG. 20 is a diagram showing a hardware configuration example of thedisplay control device 10 according to an embodiment of the presentdisclosure. It should be noted that the hardware configuration exampleshown in FIG. 20 is merely an example of a hardware configuration of thedisplay control device 10. Accordingly, the hardware configuration ofthe display control device 10 is not limited to the example shown inFIG. 20.

As shown in FIG. 20, the display control device 10 includes a centralprocessing unit (CPU) 801, read only memory (ROM) 802, random accessmemory (RAM) 803, a sensor 804, an input device 808, an output device810, a storage device 811, a drive 812, an imaging device 813, and acommunication device 815.

The CPU 801 functions as an arithmetic processing unit and a controlunit, and controls entire operation of the display control device 10 inaccordance with various programs. Further, the CPU 801 may be amicroprocessor. The ROM 802 stores a program, a calculation parameter,and the like used by the CPU 801. The RAM 803 temporarily stores aprogram used in execution of the CPU 801, a parameter varying asappropriate during the execution, and the like. The CPU 801, the ROM802, and the RAM 803 are connected with each other via the host busconfigured from a CPU bus or the like.

The sensor 804 includes various types of detection sensors such as aterminal state detection sensor for detecting states of the displaycontrol device 10, and a peripheral circuit thereof. Examples of thesensor 804 include a tilt sensor, an acceleration sensor, an orientationsensor, a temperature sensor, a humidity sensor, and a light intensitysensor. A detection signal obtained by the sensor 804 is transmitted tothe CPU 801. In this way, the CPU 801 can know the states (tilt,acceleration, orientation, temperature, humidity, light intensity, andthe like) of the display control device 10.

The input device 808 is configured from, for example, an input part forinputting information by a user, such as a mouse, a keyboard, a touchpanel, a button, a microphone, a switch, and a lever, and an inputcontrol circuit which generates an input signal based on the input bythe user and outputs the generated input signal to the CPU 801. The userof the display control device 10 can input various kinds of data to thedisplay control device 10 and can instruct the display control device 10to perform a processing operation by operating the input device 808.

The output device 810 includes, for example, display devices such as aliquid crystal display (LCD) device, an organic light emitting diode(OLED) device, and a lamp. Further, the output device 810 includes audiooutput devices such as a speaker and headphones. For example, thedisplay devices each display a captured image, a generated image, andthe like. On the other hand, the audio output devices each convert audiodata and the like into audio and output the audio.

The storage device 811 is a device for storing data, which is configuredas an example of a storage of the display control device 10. The storagedevice 811 may include, for example, a storage medium, a recordingdevice for recording data in the storage medium, a reading device forreading out the data from the storage medium, and a deletion device fordeleting the data recorded in the storage medium. The storage device 811stores a program and various data executed by the CPU 801.

The drive 812 is a reader/writer for the storage medium and is built inor externally attached to display control device 10. The drive 812 readsout information recorded in a removable storage medium 71 which ismounted thereto, such as a magnetic disk, an optical disc, amagneto-optical disk, or semiconductor memory, and outputs theinformation to the RAM 803. Further, the drive 812 can also writeinformation in the removable storage medium 71.

The imaging device 813 includes an imaging optical system, such as ashooting lens and a zoom lens for focusing light, and a signalconversion device, such as a charge coupled device (CCD) or acomplementary metal oxide semiconductor (CMOS). The imaging opticalsystem focuses light emitted from a subject and forms an image of thesubject on a signal conversion part, and the signal conversion deviceconverts the formed image of the subject into an electrical imagesignal.

The communication device 815 is a communication interface which isconfigured from, for example, a communication device for establishing aconnection with a network. In addition, the communication device 815 maybe a wireless local area network (LAN) enabled communication device, along term evolution (LTE) enabled communication device, or a wiredcommunication device for performing wired communication. Thecommunication device 815 can communicate with other devices via anetwork 30.

Heretofore, a hardware configuration example of the display controldevice 10 according to an embodiment of the present disclosure has beendescribed.

2. CONCLUSION

As described above, according to the embodiments of the presentdisclosure, there is provided the display control device 10 includingthe display controller 115 configured to place a virtual object withinan AR space corresponding to a real space in accordance with arecognition result of a real object A1 shown in an image captured by theimaging part 120, and the operation acquisition part 111 configured tocapture a user operation. In the case where the user operation is afirst operation, the display controller 115 moves the virtual objectwithin the AR space. According to such a configuration, it becomespossible to change a position of the virtual object placed in the ARspace in accordance with a user's intention.

Further, according to the position/attitude control and the size controlon the virtual object of an embodiment of the present disclosure, whenthe user Ua performs an operation of enlarging a virtual object up to areal size, for example, there may occur a case where it is necessary forthe user Ua to move away from the virtual object in order to fit thevirtual object within the imaging range in the process of the operationof enlarging the virtual object. By making the user Ua perform such anoperation, it becomes possible for allowing the user Ua to grasp thereal size of the virtual object more intuitively.

In an embodiment of the present disclosure, as a scene for moving thevirtual object within the AR space and adjusting the size of the virtualobject, the scene is mainly assumed where a photograph is taken in whicha virtual object is fit within the imaging range. However, an embodimentof the present disclosure may be applied to any scene other than such ascene. For example, an embodiment of the present disclosure can beeffectively applied also to a scene in which a virtual object whichappears in a game application is moved within the AR space and the sizeof the virtual object is adjusted.

Further, in an embodiment of the present disclosure, the description hasbeen mainly made of the example that the result of controlling thevirtual object by the display control device 10 is reflected in the ARspace of the display control device 10. However, for example, in thecase where a single AR space is shared between the display controldevice 10 and other devices, the result of controlling the virtualobject by the display control device 10 may be reflected in the AR spaceof the other devices which are communicable with the display controldevice 10.

It should be understood by those skilled in the art that variousmodifications, combinations, sub-combinations and alterations may occurdepending on design requirements and other factors insofar as they arewithin the scope of the appended claims or the equivalents thereof.

Further, it is also possible to create a program for causing hardwaresuch as a CPU, ROM, and RAM, which are built in a computer, to exhibitsubstantially the same functions as those of respective structures ofthe display control device 10 described above. Further, there is alsoprovided a non-transitory computer-readable recording medium having theprogram recorded thereon.

Additionally, the present technology may also be configured as below.

(1) A display control device including:

a display controller configured to place a virtual object within anaugmented reality space corresponding to a real space in accordance witha recognition result of a real object shown in an image captured by animaging part; and

an operation acquisition part configured to acquire a user operation,

wherein, when the user operation is a first operation, the displaycontroller causes the virtual object to move within the augmentedreality space.

(2) The display control device according to (1),

wherein, when the user operation is the first operation, the displaycontroller causes the virtual object to move within the augmentedreality space under a state where a relative position relationshipbetween the imaging part and the virtual object is maintained.

(3) The display control device according to (1) or (2),

wherein, when the user operation is the first operation, the displaycontroller causes one or a plurality of virtual objects specified by thefirst operation to move within the augmented reality space.

(4) The display control device according to any one of (1) to (3),

wherein, while the display controller causes the virtual object to movewithin the augmented reality space, the display controller causes a factthat the virtual object is being moved to be displayed.

(5) The display control device according to any one of (1) to (4),

wherein, while the first operation is not being performed, the displaycontroller fixes the virtual object within the augmented reality space.

(6) The display control device according to (5),

wherein, while the first operation is not being performed, the displaycontroller causes a size of the virtual object in the image to bechanged in accordance with a distance between the imaging part and thevirtual object.

(7) The display control device according to (5),

wherein, while the first operation is not being performed, the displaycontroller causes an attitude of the virtual object in the image to bechanged in accordance with an attitude of the virtual object based onthe imaging part.

(8) The display control device according to any one of (1) to (7),

wherein the display controller controls the virtual object on a basis ofan environment of the virtual object at a destination.

(9) The display control device according to (8),

wherein, when the environment of the virtual object at the destinationis a movement-incapable region, the display controller causes a positionof the virtual object to be shifted to a movement-capable region.

(10) The display control device according to any one of (1) to (9),

wherein the first operation includes an operation of specifying thevirtual object using one or a plurality of operating objects.

(11) The display control device according to (1),

wherein, when the user operation is a second operation, the displaycontroller changes a size of the virtual object in the augmented realityspace on a basis of the second operation.

(12) The display control device according to (11),

wherein, when the size of the virtual object in the augmented realityspace has reached a real size of the virtual object, the displaycontroller stops enlarging the virtual object.

(13) The display control device according to (11) or (12),

wherein, when the size of the virtual object in the augmented realityspace has reached a real size of the virtual object, the displaycontroller causes a fact that the size of the virtual object in theaugmented reality space has reached the real size of the virtual objectto be displayed.

(14) The display control device according to any one of (11) to (13),

wherein the display controller determines whether the size of thevirtual object in the augmented reality space has reached a real size ofthe virtual object on a basis of known data related to a real size ofthe real object, a size of the real object in the image, and known datarelated to the real size of the virtual object.

(15) The display control device according to any one of (11) to (14),

wherein, when a selection operation is performed, the display controllerselects a virtual object a size of which is to be changed on a basis ofthe selection operation.

(16) The display control device according to any one of (11) to (14),

wherein the display controller selects a virtual object a size of whichis to be changed in accordance with distances from the imaging part andthe respective one or plurality of virtual objects.

(17) The display control device according to any one of (11) to (16),

wherein the second operation includes an operation of making a distancebetween a plurality of operating objects larger.

(18) The display control device according to (1),

wherein the display controller places the virtual object in a mannerthat the virtual object has an attitude corresponding to a gravityvector.

(19) A display control method including:

placing a virtual object within an augmented reality space correspondingto a real space in accordance with a recognition result of a real objectshown in an image captured by an imaging part;

acquiring a user operation; and

causing the virtual object to move within the augmented reality spacewhen the user operation is a first operation.

(20) A non-transitory computer-readable recording medium having aprogram recorded thereon, the program being for causing a computer tofunction as a display control device including

a display controller configured to place a virtual object within anaugmented reality space corresponding to a real space in accordance witha recognition result of a real object shown in an image captured by animaging part, and

an operation acquisition part configured to acquire a user operation,

wherein, when the user operation is a first operation, the displaycontroller causes the virtual object to move within the augmentedreality space.

What is claimed is:
 1. A display control device comprising: an imagecapturing device configured to capture an image of a real space; a touchsensor configured to detect a user operation; a display configured todisplay the image captured by the image capturing device; and a displaycontroller configured to place a virtual object within an augmentedreality space corresponding to the real space in accordance with arecognition result of a real object in the real space, the virtualobject displayed by being superimposed on the image, wherein, when theuser operation is an operation specifying the virtual object, thedisplay controller moves the virtual object within the augmented realityspace on a basis of an environment of a destination of the real spacecorresponding to a predetermined position of the augmented reality spacewhere the virtual object is moved.
 2. The display control deviceaccording to claim 1, wherein the display controller causes the virtualobject to move within the augmented reality space in accordance with achange of a position and attitude of the image capturing device.
 3. Thedisplay control device according to claim 2, wherein the displaycontroller causes the virtual object to move within the augmentedreality space under a state where a relative position relationshipbetween the image capturing device and the virtual object is maintained.4. The display control device according to claim 1, wherein the displaycontroller causes the virtual object to move within the augmentedreality space with a predetermined motion.
 5. The display control deviceaccording to claim 1, wherein the operation specifying the virtualobject includes using one or more operating objects to specify thevirtual object.
 6. The display control device according to claim 5,wherein the operation specifying the virtual object includes anoperation of tapping the virtual object.
 7. The display control deviceaccording to claim 1, wherein the display control device is asmartphone.
 8. The display control device according to claim 1, whereinthe display controller is further configured to change a size of thevirtual object based on an operation of changing a distance betweenmultiple operating objects detected by the touch sensor.
 9. The displaycontrol device according to claim 8, wherein the display controller isfurther configured to limit a size change of the virtual object.
 10. Thedisplay control device according to claim 8, wherein the operation ofchanging a distance between multiple operation objects is pinch-openoperation.
 11. The display control device according to claim 1, whereinthe display controller places the virtual object in a manner that thevirtual object has an attitude corresponding to a gravity vector. 12.The display control device according to claim 1, wherein the displaycontroller places the virtual object in accordance with a position andattitude of the real object.
 13. The display control device according toclaim 1, wherein the display controller causes a display position of thevirtual object to be shifted to the destination on a basis of theenvironment of the virtual object at the destination.
 14. The displaycontrol device according to claim 13, wherein the display controllercauses a display position of the virtual object to be shifted to amovement-capable region on a basis of the environment of the virtualobject at the destination.
 15. The display control device according toclaim 14, wherein, in a case where the environment of the virtual objectat the destination is a movement-incapable region, the displaycontroller causes the display position of the virtual object to beshifted to a movement-capable region on a basis of the environment ofthe virtual object at the destination.
 16. The display control deviceaccording to claim 1, wherein the display controller causes the virtualobject to perform a predetermined motion on a basis of the environmentof the virtual object at the destination.
 17. A display control methodcomprising: capturing an image of a real space; detecting a useroperation; displaying the image; placing a virtual object within anaugmented reality space corresponding to the real space in accordancewith a recognition result of a real object in the real space, thevirtual object displayed by being superimposed on the image; and moving,when the user operation is an operation specifying the virtual object,the virtual object within the augmented reality space on a basis of anenvironment of a destination of the real space corresponding to apredetermined position of the augmented reality space where the virtualobject is moved.
 18. A non-transitory computer-readable medium havingembodied thereon a program, which when executed by a computer, causesthe computer to execute a method, the method comprising: capturing animage of a real space; detecting a user operation; displaying the image;placing a virtual object within an augmented reality space correspondingto the real space in accordance with a recognition result of a realobject in the real space, the virtual object displayed by beingsuperimposed on the image; and moving, when the user operation is anoperation specifying the virtual object, the virtual object within theaugmented reality space on a basis of an environment of a destination ofthe real space corresponding to a predetermined position of theaugmented reality space where the virtual object is moved.